A desktop stapler uses a spring to store energy to install staples by impact blow. The force required to fasten papers together is reduced. A very compact mechanism is used, including a dual coil power spring with a nested lever. A multi function base provides a sloped front all the way to down to a desk top surface to guide paper sheets atop the base, easy access for lifting the stapler off a desk, horizontal or vertical resting positions, and integrated soft grip under-surface. The base surrounds the rear of the stapler body to provide a smooth exterior so that the device is natural to use both horizontally and vertically. A simple re-set spring provides a smooth re-set action as the handle is raised. A staple track includes enlargement features to fit a larger staple pusher spring.
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8. A stapling device including a body and a handle pivotably attached to the body, a staple loading chamber, a track within the loading chamber to hold and guide staples in the stapling device, a staple pusher to urge staples on the track toward a front of the stapling device, a striker to eject staples at a front of the loading chamber out of the stapling device wherein:
the body includes two assembled halves defining an interior space of the body;
the handle includes bosses that engage recesses within the body, the bosses and recesses defining a pivot location of the handle upon the body, the handle bosses extending outward from the handle, the recesses extending into sidewalls of the interior space of the body; the handle able to be installed into an assembled position in the interior space of the body by forcibly separating the halves of the body.
10. A stapling device for dispensing staples comprising:
a handle pivotably mounted to a housing body;
the body having a front end and a hinge connection proximate to a rear end;
a base pivotably engaging the body at the hinge connection;
a striker slidably disposed in the body proximate to the front end thereof;
a track disposed beneath the striker for holding the staples, wherein the striker is biased to move toward the track to impact the staples;
a lever having a front end, a back end, a pivot axis therebetween, and a tab in between the pivot axis and the back end, wherein the pivot axis pivots against the body, the handle rotatably engages the tab, and the lever front end selectively lifts the striker against the bias;
a re-set spring disposed rearward of the lever pivot axis and engaging the lever back end and body, urging the lever front end toward the track to re-engage the striker; and
wherein the lever includes a relatively straight flat plate having a slight bend in a central portion to accommodate the re-set spring proximate thereto.
1. A stapling device for dispensing staples comprising:
a handle pivotably mounted to a housing body;
the body having a front end and a hinge connection proximate to a rear end;
a base pivotably engaging the body at the hinge connection;
a striker slidably disposed in the body proximate to the front end thereof;
a track disposed beneath the striker for holding the staples, wherein the striker is biased to move toward the track to impact the staples;
a lever having a front end, a back end, a pivot axis therebetween, and a tab in between the pivot axis and the back end, wherein the pivot axis pivots against the body, the handle rotatably engages the tab, and the lever front end selectively lifts the striker against the bias, and wherein the lever pivot axis includes an elongated slot pivotably and slidably mounted to the body so that the re-set spring further urges the lever to slide linearly toward the body front end; and
a re-set spring disposed rearward of the lever pivot axis and engaging the lever back end and body, urging the lever front end toward the track to re-engage the striker.
11. A stapling device for dispensing staples comprising:
a handle having a front end and a pivot proximate to a rear end;
a housing body having a front end and hinge connection proximate to a rear end, wherein the handle pivot engages the body forward of the hinge connection;
a base having a front and a rear wall with opposed sidewalls, wherein the body hinge connection pivotably engages the base at the sidewalls;
a striker slidably disposed in the body proximate to the front end thereof;
a track disposed beneath the striker within the body for holding the staples, wherein the striker is biased to move toward the track to impact the staples;
a lever having a front end, a back end, a pivot axis therebetween, and a tab in between the pivot axis and the back end, wherein the pivot axis pivotably engages the body, the handle selectively engages the tab, and the lever front end selectively lifts the striker against the bias;
a re-set spring disposed rearward of the lever pivot axis and engaging the lever back end and body, urging the lever back end away from the track and lowering the lever front end to re-engage the striker; and
wherein the lever pivot axis includes an elongated slot pivotably and slidably disposed on the body so that the re-set spring further urges the lever to slide linearly toward the body front end.
6. A stapling device including a body and a handle pivotably attached to the body at a rear of the stapling device wherein:
the handle has a rest position where the handle is pivoted to an upper position away from the body, the handle has a pre-release position where the handle is pivoted down toward the body, and the handle has a re-set position intermediate between the rest position and the pre-release positions;
a striker is movable within the body and is linked to the handle through a lever whereby pressing the handle toward the body causes the striker to rise in the body;
the handle presses a lever tab at a rear of the lever and the lever pivots about a lever axis within the body;
a power spring within the body is linked to the striker whereby raising the striker causes the power spring to deflect and store energy;
at a predetermined position of the handle the lever suddenly releases the striker and the striker ejects a staple out of a staple loading chamber as the power spring returns to a rest position;
a re-set spring pushes upward upon the lever at a rear portion of the lever behind the lever axis, the re-set spring causing a downward bias upon a front portion of the lever;
the re-set spring engaging the lever at a position rearward of both the lever tab and the lever axis;
wherein a re-set stroke of the lever includes a first step where the lever front distal end moves from above the striker downward to a toy edge of the striker, a second step where the lever front distal end moves to behind the striker, and a third step where the lever front distal end moves forward into a slot in the striker;
the re-set spring comprises a torsion spring, a lower arm of the torsion spring pivotally attached to the body, an upper arm pivotally attached to the lever, a coil of the re-set spring positioned forward from the attachments of the upper and lower arms and movable with the body;
the re-set spring pushes upward upon the lever during the first step and second steps, and the re-set spring pushes upward and forward upon the lever during the third step;
the coil of the re-set spring moves rearward as the arms of the reset spring move apart during the re-set stroke, the coil of the re-set spring contacts a rib of the body during the third step of the re-set stroke.
2. The stapling device of
3. The stapling device of
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The present invention relates to desktop staplers. More precisely the present invention discloses improvements to a spring-actuated stapler.
In a common desktop stapler a striker is linked directly to a handle so that pressing the handle ejects a staple out and through a stack of papers. Three distinct forces must be overcome: breaking off the staple from the rack of staples, piercing the papers, and folding the staple legs behind the papers. As the staple moves through the cycle there are force peaks and force lows. The result is a jerky experience as the user forces the handle down. The handle resists, suddenly gives way, and then resists again. Even though the peak forces are for short durations, they define the difficulty of using a stapler. Empirical information suggest that a conventional stapler requires peak forces of 15 to 30 pounds, depending on the number of paper sheets to be fastened.
It is desirable to limit the peak force required. An effective way to do this is to accumulate the total energy needed to install the staple and then release that energy all at once by striking the staple in an impact blow. This is a type of action commonly used in staple gun tackers. A handle is pressed through a range of motion causing a spring to store energy. The stored energy is suddenly released at a predetermined handle position. A striker linked to the spring ejects and installs a staple. released at a predetermined handle position. A striker linked to the spring ejects and installs a staple.
An important advantage of using stored energy to install a staple is that the handle end need not be directly linked to the striker. In a common direct acting desktop stapler the handle front end moves exactly as the staple moves. This means that, for example, 15 lbs to force a striker, thus a staple, to move 1 mm requires 15 lbs to move the handle that same 1 mm. If the driving energy is stored, then the handle can be delinked from the striker. The handle can move more than the striker moves to provide enhanced leverage. For example the handle, where it is pressed near its front end, may move downward one inch as the spring is deflected, while the striker moves just ½ inch when the spring is released. According to the preceding discussion, the peak force in stapling can be reduced through two ways. First, using stored energy allows removal of force peaks by averaging forces over a full handle motion. Second, the energy can be stored through a leveraged system.
A stapler must have a method for adding staples to a staple track. In a common direct acting stapler the striker has a rest position immediately above the staple to be ejected. The track may move outward from the front of the stapler to expose a staple loading area since the striker does not obstruct such motion. Or the handle may be linked to a staple pusher whereby pivoting the handle away from the track causes the pusher to retract while the track becomes exposed.
In a practical spring actuated stapler these two common loading systems are not easily provided. The striker rests in its down position just in front of the staple rack. It is not possible to slide the track out past the obstruction created by the striker. Further, since there is an energy storage mechanism linking the striker to the handle in the spring-actuated stapler, it would require a complex design to provide for exposing the staple track by pulling the handle away from the track. An alternate staple loading design is needed.
Among the prior art is UK Patent GB2229129. A spring actuated heavy-duty desktop stapler includes a two piece molded housing with a double torsion (two coil) power spring. A lever has a “U” channel section, and engages an extended handle by means of a roller linkage.
German Patent DT2856-621 shows a staple gun that uses a similar mechanism to the above '129 reference, but as a staple gun tacker, without a base or a forward handle linked to the lever.
U.S. Pat. No. 4,463,890 discloses a standard style desktop stapler with a spring-actuated driver. The striker has a raised rest position, above the staples as in typical direct action staplers. Base 10 overhangs rubber footpads under the base at the distal front and rear ends of base 10.
U.S. Pat. No. 2,271,479 shows a stapler with footpads slightly more closely integrated with the base. The front footpad angles upward and forward to meet the lower edge of the base, leaving a notch under the base.
UK Patent GB2032327 shows re-set spring 12 attached to lever 3 rearward of lever pivot 4.
U.S. Pat. Nos. 5,988,478 and 6,145,728, to the present inventor, show forward action staple guns. In both references the lever has a “U” channel section that partially surrounds the power spring from above. In '728 lever 60 engages striker 80 by two opposed openings 83. Power spring 70 fits into striker opening 87 between the opposed lever openings. In '478, the handle is pivoted to the body by arcuate extensions 32 surrounding post 12.
U.S. Design Pat. Nos. 186,342, B396,377, D413,239, D437,754, show various base designs. A short center portion of the base is actually or visually raised in these designs.
U.S. Pat. No. 5,699,949 to the present inventor shows a further forward action staple gun. A staple track is at the bottom of the device, behind the numeral 50 in FIG. 1, formed as an upright “U” metal channel. A staple track guiding tab of the track is seen just to the left and above the numeral 5 in FIG. 1. An opening is seen in the side of the track from which the tab has been formed. A pusher spring resembling a cross hatch shows through this opening in FIG. 1. The tab is made from a cut out portion of the side of the “U” channel.
U.S. Pat. No. 2,218,794 shows a spacer spring 39 that serves a function to releasably limit upward motion of the body through a snap fit. Elongated “ears or bearings 11” position the body laterally above the base in a conventional way by contact between the body sides and the elongated bearings 11. Spring 39 includes various out-of-plane bends to allow it to change length as the body closes against the base. It is therefore not stiff in the lateral direction. Further, rivet 38 does not provide substantial lateral stiffness to spring 39.
U.S. Pat. No. 4,546,909 shows a stapler with a spacer spring a3 or a4 formed as a “punched out” element.
U.S. Pat. No. 4,795,073 shows a spacer spring 19 that is apparently molded as part of the base.
U.S. Pat. No. 4,811,884 shows a base with a rearward attachment to the body. Groove 107 engages tab 108 to hold the base in the fully open position, col. 9, lines 5-13.
In the present invention a desktop stapler includes improvements to increase ease of use and modes of use. A spring is linked to a striker so that when the striker is raised and suddenly released the stored energy of the spring drives a staple through a stack of papers to be fastened together. A handle is pressed to raise the striker and store energy in the spring. Improvements of the invention include: a very compact mechanism to maintain a conventional looking size of the stapler, a smooth re-set action as the handle is raised, a simplified handle pivot connection and assembly method, a spring to raise the stapler body away from the base where the spring is integrated into a base cover plate, the base cover plate further including a staple forming anvil, a press fitted connection between the body and the base, a novel method to accurately position the body front end over the anvil, a location for a staple loading track that is convenient and compatible with a striker that maintains a lowered rest position, a rear distal end of the body resiliently engages a rib of the base to create a releasable detent holding the body in a maximum up position from the bias of the body raising spring, and a base that is raised along the majority of its length and is convex in its underside to facilitate lifting the stapler off a table. A further operational mode allows that the stapler rests on a desk in a front down vertical position so that it may be most easily lifted up for use.
A staple loading system includes a track pull element that is normally hidden from view. Pivoting the body up from and rearward of the base exposes the track pull for operation.
An advantage of the present invention is that the low operating force makes it easy to use with an extended hand on a desk. It is even practical to press by fingertips.
Handle 30 between corners 35 may be straight or concave. It is slightly concave in at least one portion as seen in FIG. 14. The front face defined by corners 35 allows the stapler to be stable in a vertical position on a desk,
Three points support the stapler in the vertical position, the two corners 35, and base front end 28, preferably at the central forward edge of footpad 121. As a design choice front end 28 may be flat, with respect to a top view, to provide a longer support surface. However in the illustrated embodiment most of the weight in the vertical position is supported at the handle, so corners 35 provide good support. As seen in
The forward edge of footpad 121 extends to sharp edge 121a,
To best fit the components of the stapler in a compact body shape, a single relatively thick plate lever 40 is used rather than a thinner steel inverted U channel lever design. Lever front end 48 thus extends through single central slot 108 under a tall center portion of striker 100, FIG. 8. Lever 40 includes a centrally aligned front portion and a rear portion out of plane from the front portion, defined at bend 43, FIG. 14. The rear portion is to one side in body 10, into the page in
Preferably handle 30 presses tab 44 through a low friction linkage. In
Striker 100 is fitted along two edges in guide channels 11 of housing 10, FIG. 5. The location where slip link 130 presses tab 44 is substantially coplanar with slot 46 and lever front end 48. Lever 40 is flat in the area of slot 46. In
Power spring 90 stores energy for installing staples. Spring 90 is linked to handle 30 through lever 40 and striker 100. Lever 40 pivots about pin 49 at slot 46 to raise striker 100 at lever front distal end 48,
As handle 30 is forced downward to the position of
When boss 32, the contact point, and pin 49 are aligned, there is a neutral condition with no sliding. In
The effect of the above discussion of the contact point is a varying leverage action of the handle upon the lever. The handle moves the lever quickly with low leverage at the start of the stroke,
In the re-set action it is desirable to maintain a downward bias upon pin 49 by lever 40 so that there is no take-up or “rattle” within slot 46 as the next power stroke begins. For example if a re-set spring causes an upward force at pin 49, pin 49 will press the bottom edge of slot 46. As the power stroke begins slot 46 will press pin 49 at the opposing upper slot edge. The lever will unproductively move as slot 46 adjusts about pin 49. To prevent this wasted motion re-set spring upper end 72 is fitted in lever hole 42, rearward of tab 44. Hence as slip link 130 presses down on tab 44, and spring end 72 presses up on the rear end of the lever at hole 42, all points on the lever forward of tab 44, including slot 46, are biased downward. A tab notch or other engaging feature of lever 40 may serve the function of hole 42.
Re-set spring 70 includes features at each end to hold the spring in place. During assembly lower re-set spring end 74 is normally installed first into hole 19 of the left half of housing 10, FIG. 25. Hole 19 is larger in diameter than the wire of spring 70. Spring end 74 includes a short bent segment 74a,
During the re-set stroke handle 30 rotates upward as tab 44 presses handle 30 upward, through slip link 130, from the bias of re-set spring 70. Handle 30 rotates at recess 12 of body 10 about a boss 32 on each side of the handle. Body 10 preferably includes chamfers 13 aligned with bosses 32,
The stapler includes a normal closed position. In the closed position the body is substantially parallel and spaced from base 20, as shown in most of the Figures of the complete assembly.
Spring 52 extends upward and forward. The resulting geometry ensures that spring 52 will not interfere with any papers that are inserted all the way to sidewalls 23;
Tab 54 aligns in the lateral direction, vertical in
Base 20 includes elongated raised under-portion 24 to provide a gap between a tabletop and the stapler. The gap creates a substantial area from which to get fingers under and lift the stapler. Front foot 26 and rear foot 25 are features that serve to hold up raised portion 24. Raised portion 24 has a convex outer sectional surface to further facilitate inserting fingers under base 20. To form the main component of convex base 20 by molding, a reasonably thin wall must be used according to standard molding practice. The thin wall creates cavity 27,
Cover plate 50 is held to base 20 without the use of additional components or specialized operations. Tab 56 of the cover plate extends below undercut 256 of base 20, FIG. 18. Ribs 250, or another part of base 20 near sidewalls 23, create a friction fit to hold cover plate 50 against shelf 251. Ribs 250 engage corresponding notches in the cover plate to position cover plate 50 longitudinally, left to right in FIG. 19. To assemble, cover plate 50 is tilted so that tab 56 enters undercut 256. The cover plate is then lowered at its rear and pressed into place between sidewalls 23. Spacer spring 52 normally provides pressure to hold cover plate 50 down at its rear giving a redundant holding feature. Cavity 27 may include flattened portion 227 to fit a steel bar for additional weight in the base.
The rear end of the stapler of the invention presents a clean simple appearance, FIG. 4. Sidewalls 23 are joined by rear wall 29,
Using extension 67 to hold the body with a slight preload on spring 52 provides a stiff structure. If for example, the body were held down at tab 54 of spring 52 by a frictional engagement between tab 54 and opening 84, the body would bounce over the base since an unloaded spring is doing all of the holding. This would suggest low quality design.
Squeezing track pull arms 65 releases track locks 62 from catches 262,
Staple pusher 180 fits over track 80 to urge staples, not shown, that are guided by track 80 toward striker 100,
To store the most energy spring 300 needs a maximum number of coils and maximum coil diameter, to effectively pack the longest possible wire in the available space. This possible wire length is a function of the overall length of track 80 and an internal area enclosed by both the track and the pusher that can fit the coil diameter. The internal transverse sectional area of the track with pusher is determined by the size of the staples that the track is designed to carry. A wider track will not fit within a specified staple leg dimension, and a taller track will require striker 100 to rise higher than necessary to clear the top of the staples, requiring a taller overall stapler device since striker channel upper end 11b would need to be higher. Standard desktop staples are relatively wide and short compared to tacker staples.
According to the present invention, a larger interior space enclosed by the track for the coil of spring 300 is provided by creating an effectively taller space, while still fitting wide short staples. In
To further increase the available spring area, pusher 180 includes centrally aligned arcuate hump 185 co-axial with the coils of spring 300. Arcuate channel 145,
Tabs 87 are formed from cutouts 82 of the bottom of track 80. Rib 89 forms a divider between cutouts 82. This design contrasts with that of U.S. Pat. No. 5,699,949 where the tabs are formed from cutouts of the track sides. Using cutouts from the bottom is desirable in the present invention light duty stapler where the staples and thus the track sides are short compared to staple gun tackers. Forming the tabs from the sides would leave little material on the side. Rib 89 provides stiffness to the bottom of the track.
Bumper 146 provides a stop for power spring 90,
Hinge connection 22 with post 15 is shown in section in
For assembly, housing 10 is forced in-between sidewalls 23. The tapered ends of posts 15 form ramps to spread apart sidewalls 23 as posts 15 begin to press edges of sidewalls 23 during assembly. Hinge connections 22 are at movable portions of sidewalls 23,
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Dec 17 2002 | MARKS, JOEL S | Worktools, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 015693 | /0745 | |
May 23 2003 | WorkTools, Inc. | (assignment on the face of the patent) | / |
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